7776-48-9

Usage

Uses

Used in the Food Industry:
L-Fructose is used as a sweetener for its natural sweetness, which is often more pronounced than that of sucrose. It is favored for its ability to enhance the taste of various food products without contributing to tooth decay or raising blood glucose levels as much as other sugars.
Used in the Pharmaceutical Industry:
L-Fructose is utilized as an ingredient in the formulation of certain medications, particularly those aimed at providing quick energy or addressing specific dietary needs, such as in the case of diabetes management.
Used in the Sports Nutrition Industry:
L-Fructose is used as an energy source in sports drinks and supplements, providing athletes with a quick source of energy during physical activity.
Used in the Cosmetics Industry:
L-Fructose is sometimes included in cosmetic products for its moisturizing properties, as it can help to maintain skin hydration and improve overall skin health.
Used in the Chemical Industry:
L-Fructose can be used as a starting material for the synthesis of various chemicals and compounds, such as biofuels and other industrial products.

InChI:InChI=1/C6H12O6/c7-1-3(9)5(11)6(12)4(10)2-8/h3,5-9,11-12H,1-2H2/t3-,5-,6-/m0/s1

Upstream product

• 57-48-7 fructose 
• 78184-44-8 Penta-O-acetyl-keto-L-fructose 
• 57-04-5 dihydroxyacetone phosphate 
• 497-09-6 (S)-glyceraldehyde 
• 643-01-6 L-mannitol 
• 20880-92-6 2,3:4,5-di-O-isopropylidene-β-L-fructopyranose 
• 87-79-6 L-sorbose 
• 19456-80-5 L-fructose-1-phosphate 
• 96-26-4 dihydroxyacetone 
• 56-82-6 Glyceraldehyde 
• 78124-21-7 3,4,5,6-tetra-O-acetyl-1-deoxy-1-diazo-L-fructose 
• 57-48-7 D-Fructose 
• 57-48-7 L-fructose 
• 69-65-8 mannitol 

Downstream Products

• 57-48-7 fructose 
• 15080-25-8 1,2:4,5-di-O-isopropylidene-β-L-fructopyranose 
• 1232836-54-2 1,3,4,6-tetra-O-benzoyl-α-L-fructofuranosyl acetate 
• 1232836-53-1 C₃₄H₂₈O₁₀ 
• 1232836-52-0 C₃₄H₂₈O₁₀ 
• 624-45-3 levulinic acid methyl ester 
• 13403-14-0 methyl β-D-fructofuranoside 
• 849585-22-4 LACTIC ACID 
• 67-64-1 acetone 
• 26832-08-6 imidazole-4-carboxamide 
• 23275-67-4 lyxo-[2]Hexosulose-bis-phenylhydrazon 
• 39131-44-7 5-bromomethyl-furan-2-carbaldehyde 
• 50-00-0 formaldehyd 
• 79-14-1 glycolic Acid 

Relevant academic research and scientific papers

Hydroxyapatite-Supported Polyoxometalates for the Highly Selective Aerobic Oxidation of 5-Hydroxymethylfurfural or Glucose to 2,5-Diformylfuran under Atmospheric Pressure

(NH4)5H6PV8Mo4O40 supported on hydroxyapatite (HAP) (PMo4V8/HAP (n)) was prepared through the ion exchange of hydroxy groups. This ion exchange favored the oxidative conversion of 5-hydroxymethylfurfural (5-HMF) to 2,5-diformylfuran (DFF) in a one-pot cascade reaction with 96.0 % conversion and 83.8 % yield under 10 mL/min of O2 flow. PMo4V8/HAP (31) was used to explore the production of DFF directly from glucose with the highest yield of 47.9 % so far under atmospheric oxygen, whereas the yield of DFF increased to 54.7 % in a one-pot and two-step reaction. These results indicated that the active sites in PMo4V8/HAP (31) retained their activities without any interference toward one another, which enabled the production of DFF in a more cost-saving way by only using oxygen and one catalyst in a one-step reaction. Meanwhile, the rigid structure of HAP and strong interaction in PMo4V8/HAP (31) allowed this catalyst to be reused for at least six times with high stability and duration.

Few-Unit-Cell MFI Zeolite Synthesized using a Simple Di-quaternary Ammonium Structure-Directing Agent

Synthesis of a pentasil-type zeolite with ultra-small few-unit-cell crystalline domains, which we call FDP (few-unit-cell crystalline domain pentasil), is reported. FDP is made using bis-1,5(tributyl ammonium) pentamethylene cations as structure directing agent (SDA). This di-quaternary ammonium SDA combines butyl ammonium, in place of the one commonly used for MFI synthesis, propyl ammonium, and a five-carbon nitrogen-connecting chain, in place of the six-carbon connecting chain SDAs that are known to fit well within the MFI pores. X-ray diffraction analysis and electron microscopy imaging of FDP indicate ca. 10 nm crystalline domains organized in hierarchical micro-/meso-porous aggregates exhibiting mesoscopic order with an aggregate particle size up to ca. 5 μm. Al and Sn can be incorporated into the FDP zeolite framework to produce active and selective methanol-to-hydrocarbon and glucose isomerization catalysts, respectively.

Bi-Functional Magnesium Silicate Catalyzed Glucose and Furfural Transformations to Renewable Chemicals

Bio-refinery is attracting significant interest to produce a wide range of renewable chemicals and fuels from biomass that are alternative to fossil fuel derived petrochemicals. Similar to petrochemical industries, bio-refinery also depends on solid zeolite catalysts. Acid-base catalysis plays pivotal role in producing a wide range of chemicals from biomass. Herein, the Mg framework substituted MTW zeolite is synthesized and explored in the valorisation of glucose and furfural. Bi-functional (acidic and basic) characteristics are confirmed using pyridine adsorbed FT?IR analysis and NH3 and CO2 temperature-programmed desorption techniques. Textural properties and morphological information are retrieved from N2-sorption, X-ray photoelectron spectroscopy, and electron microscopy. The activity of the catalyst is demonstrated in the selective isomerisation of glucose to fructose in ethanol. Glucose is converted to methyl lactate in high yield using the same catalyst. Further, the bi-functional activity of this catalyst is demonstrated in the production of fuel precursor by the reaction of furfural and isopropanol. Mg?MTW zeolite exhibits excellent activity in the production of all these chemicals and fuel derivative. The catalyst exhibits no significant loss in the activity even after five recycles. One simple catalyst affording three renewable synthetic intermediates from glucose and furfural will attract significant attention to catalysis researchers and industrialists.

Method for preparing fructose (by machine translation)

The method comprises the following steps: (1) reacting glucose with a catalyst in the presence of alcohol and carrying out reaction to obtain fructose-containing product; wherein the weight ratio of the glucose to the mixture of the titanium silicalite molecular sieve and the tin-silicon molecular sieve 50 - 600 is below 30 °C: (100 °C 0.1 - 6 1 1 - 10h) The method disclosed by the invention has high glucose conversion rate and fructose yield. (by machine translation)

PROCESSES FOR PREPARING SORBOSE FROM GLUCOSE

Processes for converting glucose to sorbose with tailored selectivity. The processes include contacting glucose with a silica-containing structure that includes a zeolite having a topology of a 10-membered ring or smaller and Lewis acidic M4+ framework centers, wherein M is Ti, Sn, Zr, or Hf. Contacting the glucose is conducted under reaction conditions sufficient to isomerize the glucose to sorbose.

Method for preparing lactic acid through catalytically converting carbohydrate

The invention relates to a method for preparing lactic acid through catalytically converting carbohydrate, and in particular, relates to a process for preparing lactic acid by catalytically convertingcarbohydrate under hydrothermal conditions. The method disclosed by the invention is characterized by specifically comprising the following steps: 1) adding carbohydrate and a catalyst into a closedhigh-pressure reaction kettle, and then adding pure water for mixing; 2) introducing nitrogen into the high-pressure reaction kettle to discharge air, introducing nitrogen of 2 MPa, stirring and heating to 160-300 DEG C, and carrying out reaction for 10-120 minutes; 3) putting the high-pressure reaction kettle in an ice-water bath, and cooling to room temperature; and 4) filtering the solution through a microporous filtering membrane to obtain the target product. The method can realize high conversion rate of carbohydrate and high yield of lactic acid, and has the advantages of less catalyst consumption, good circularity, small corrosion to reaction equipment and the like.

Role of the Strong Lewis Base Sites on Glucose Hydrogenolysis

This work reports the individual role of strong Lewis base sites on catalytic conversion of glucose hydrogenolysis to acetol/lactic acid, including glucose isomerisation to fructose and pyruvaldehyde rearrangement/hydrogenation to acetol/lactic acid. Las

A catalyzed by a chemical method, a method of glucose isomerization to fructose

The invention discloses a chemical method for catalyzing glucose into fructose through isomerization, and relates to fructose. The method comprises the following steps: mixing a water solution containing Mg(NO3)2.6H2O, Al(NO3)3.6H2O, and Zr(NO3)4.5H2O/Sn(NO3).6H2O/Cu(NO3)2.3H2O with a NaOH water solution and a Na2CO3 water solution, wherein the metal molar mass ratio of Mg:Al:M is equal to 3:1:1, M represents Zr, Sn, or Cu, pH is 8 to 8, and the temperature is 60 DEG C; carrying out aging on the precipitate in the mother liquid, then carrying out static crystallization, drying so as to obtain the trinary metal hydrotalcite, adding the trinary metal hydrotalcite into a glucose solution to carry out reactions, filtering so as to obtain isomerized glucose solution and a solid hydrotalcite catalyst, recycling the catalyst, and finally subjecting the filtrate to vacuum rotation evaporation so as to obtain a condensed fructose liquid, wherein the weight ratio of the trinary metal hydrotalcite to the glucose to solvent (water) is (1-4):(1-10):40.

Facile enzymatic synthesis of ketoses

Studies of rare ketoses have been hampered by a lack of efficient preparation methods. A convenient, efficient, and cost-effective platform for the facile synthesis of ketoses is described. This method enables the preparation of difficult-to-access ketopentoses and ketohexoses from common and inexpensive starting materials with high yield and purity and without the need for a tedious isomer separation step. A spoonful of sugar: A convenient, efficient, and cost-effective platform for the facile synthesis of ketoses is described. This method, which involves a one-pot mulitenzyme (OPME) reaction, enables the preparation of rare ketopentoses and ketohexoses from common and inexpensive starting materials with high yield and purity and without the need for a tedious isomer separation step.

Characterization of glycerol phosphate oxidase from Streptococcus pneumoniae and its application for ketose synthesis

Glycerol phosphate oxidase from Streptococcus pneumoniae (GPOS.pne) was purified and characterized. By the actions of GPOS.pne and dihydroxyacetone phosphate (DHAP)-dependent aldolases, various ketoses including rare sugars were synthesized with glyceraldehydes as acceptors in a one-pot four-enzyme system.